DE4021944C2 - - Google Patents

Description

The invention relates to a reflection factor measuring bridge according to the preamble of the main claim.

Reflection factor measuring bridges of this type are known (e.g. measuring bridge ZRB2 from Rohde & Schwarz). At Measuring bridges of this type will both the high-frequency Sig source as well as the test object via coaxial connection sockets connected. With some measuring objects is during a DC power supply during the measurement process the built-in components such as transistors or diodes via the coaxial connection point. It is known for this a special coaxial adapter to be placed between the test object and the measuring bridge. It is also known to direct current across one of the bridges supply resistance and for this purpose the Hochfre quenz signal source via a transformer with the Bridge diagonal to connect (US 32 27 953). This one known measures, the disadvantage is that this affects the symmetry of the bridge and thus their properties are deteriorated.

It is an object of the invention to provide a circuit for feeding a DC voltage to one over a coaxial line measurement connected to a reflection factor measuring bridge to create object through which the bridge properties not get worse.  

This task is based on a reflection faculty Tor measuring bridge according to the preamble of the main claim its characteristic features solved. Beneficial Further training results from the subclaims.

Due to the compensation measure according to the invention on Symmetry transformer of the measuring bridge is achieved that the direct current supplied from both through the Compensation winding as well as in the opposite sense about the main winding of the ge through the line piece formed balun flows, in which associated ferrite core so two magnetic fluxes of the same However, amount generated from different directions that cancel each other out. So that becomes a magnetic saturation of the ferrite core even at high Avoided direct currents, the symmetry of the bridge and their directivity and customization are also not avoided worsened. This makes it possible for the first time without ver deterioration of the bridge properties over the measuring bridge To feed components in the test object with direct current. Since with the type of direct current supply according to the invention the bridge symmetry is not disturbed, is suitable this type of feed also for measuring bridges in a large Frequency range up to 5 GHz or more can be used.

There is for the formation of the compensation winding according to subclaims different options. Especially The attachment of a second is advantageous here Compensation winding on the ferrite core of the other symmetry transmission formed by the coaxial cable ger branch, although not for DC voltage supply  serves, but only from high-frequency symmetry is provided, has such an arrangement the advantage that the symmetry of the bridge is frequency independent depending largely on the supply of high direct currents remains unaffected.

The invention will now be described more schematically Drawings explained in more detail using exemplary embodiments.

Fig. 1 shows the basic structure of a Reflexionsfak tor measuring bridge, the high-frequency input 1 is connected via a coaxial socket to a high-frequency generator, not shown, via the two bridges branches R 1 , R 2 , the two connection points 2 and 3 of the bridge diagonal fed, the device under test 4 is connected via a coaxial connector 5 between the connection point 2 and ground as the third bridge branch, the precision resistor Z ₀ is connected between the connection point 3 and ground as the fourth bridge branch. The indicator 6 is connected via a coaxial cable 7 to the connection points 2 and 3 of the bridge diagonal in connection with the inner conductor 8 of this cable 7 being connected to the connection point 2 and the outer conductor 9 being connected to the connection point 3 . The lower end of the outer conductor 9 of the coaxial cable 7 is connected to ground 10 (housing of the measuring bridge).

In order to prevent a high-frequency ground fault of the connection point 3 of the bridge diagonal across the outer conductor 9 of the coaxial cable 7 , 9 ferrite cores 11 and 12 are placed on the outer conductor. These ferrite cores 11 and 12 determine the lower limit frequency of the measuring bridge. In order to achieve a large bandwidth, two different ferrite cores 11 and 12 are provided, on which the coaxial cable 7 is wound in each case with a different number of turns (N ₁ and N ₂ ). To restore the symmetry of the bridge, an additional line piece 13 is arranged parallel to this coaxial cable 7 equipped with ferrite cores, which is connected at one end again to the connection point 2 of the bridge diagonal and at the other end 18 HF-wise via a capacitor C 3 to ground 10 lies. Two ferrite cores 14 and 15 are again placed on this line piece 13 , the line piece 13 is again wound with different numbers of turns (N ₁ and N ₂ ) on the differently sized ferrite cores 14 and 15 . The coaxial cable 9 with the attached ferrite cores and the line piece 13 with the also attached ferrite cores form a symmetrizing transmitter, the two transmitter halves should be constructed as mirror-symmetrical as possible.

For DC separation of the measurement input 5 , the capacitors C 1 , C 3 and C 4 are provided, the capacitor C 2 is provided for reasons of symmetry.

For powering of active components in the measuring object 4 with direct current on the inner conductor feed 16 the desired for the measurement object 4 DC voltage terminal 18 is supplied from a DC voltage source via the terminal 17, which is for high frequency through the capacitor C 3 is grounded. In order to avoid magnetic saturation of the ferrite ring 15 in the case of larger direct currents and an associated deterioration in the symmetry of the bridge, the supply of the direct current to the connection point 18 takes place via a compensation winding, which is wound on the ferrite ring 15 in addition to the line piece 13 , preferably with the same number of turns N 2 .

Fig. 1 shows a first possibility for the formation of this additional compensation winding on the ferrite ring 15th In this exemplary embodiment, it is formed by the inner conductor 26 of a coaxial cable piece 25 , the outer conductor of which forms the continuation of the line piece 13 , so in this exemplary embodiment the winding 25 of the line piece 13 on the ferrite ring 15 is formed by a short coaxial line piece 25 . At the high-frequency end of ground 18 of the line piece 13 , the inner conductor 26 is galvanically connected to the outer conductor 27 of this coaxial line piece, this connection point is via the capacitor C 3 high-frequency back to ground. The opposite end 21 of the inner conductor 26 is connected via a high-frequency choke 22 and a low-pass filter 23 to the input terminal 17 for the DC voltage. The high-frequency choke 22 separates the connection point of the compensation winding high frequency from the DC voltage input 17th The DC supply current for the measuring object 4 thus flows through the inner conductor 26 to the high-frequency ground 18 , from there in the opposite sense through the outer conductor 27 and the adjoining line piece 13 to the bridge connection 2 and from there via the inner conductor 16 into the measuring ob ject 4 .

Fig. 2 shows a broadband embodiment of the compensation winding for the supply direct current. In this exemplary embodiment, the compensation winding is formed by an additional wire winding 19 on the ferrite core 15 , which in the exemplary embodiment shown is applied with the opposite winding direction as the winding 15 . Thus, opposite magnetic fields are generated in the ferrite core 15 at the same current direction through the windings 19 and 25 , which cancel each other. The winding 19 could also be applied in the same winding sense as the winding 25 if it is ensured that the current direction in this winding 19 is opposite to that in the winding 25 . Here, too, the number of turns of winding 19 is preferably selected to be equal to the number of turns of winding 25 . The upper end 21 of the wire winding 19 is connected to the Hochfre frequency inductor 22 , the other end is connected to the ground terminal 18 . For reasons of symmetry, a similar compensation winding 20 is applied to the ferrite ring 12 of the coaxial cable 7 of the other transformer half, with the same number of turns as the winding 19 , the winding direction is again either the same or opposite to the winding sense of the coaxial cable 7 , depending on the direction of current. The upper end 29 of this Kom compensation winding 20 is connected to the end 21 of the other compensation winding 19 with the high-frequency choke 22 , the lower end 28 is connected in the embodiment shown via a resistor 24 to the terminal 18 . The DC current supplied via the inductor 22 thus essentially flows through the compensation winding 19 to the connection point 18 , from there in the opposite sense through the winding 25 and the line piece 13 back to the bridge connection 2 . Because of the resistor 24 flows in the second compensation winding 20 only a relatively small current, so direct current moderately, the largest current component flows directly to the connection point 18 , but in terms of high frequency, both transformer branches are symmetrically loaded with similar compensation windings 19 and 20 . Instead of opposing 24 , the end 28 of the compensation winding 20 could also be connected in high frequency, for example via a capacitor, directly to the ground terminal 10 , so that no direct current flows through the winding 20 at all, so the winding 20 only fulfills its high-frequency symmetry tasks.

The additional compensation winding 20 should not even be electrically connected to the connection point 21 of the compensation winding 19 , it could be directly galvanically connected to ground 10 with its lower end 28 and with its upper free end 29 via an additional high frequency choke provided for reasons of symmetry, which the Throttle 22 corresponds, and a capacitor are high-frequency to ground, also in this case, it fulfills its symmetry task high-frequency, without being flowed through by the direct current. In the illustrated Ausführungsbei play only the larger ferrite core 15 (or the ferrite core 12 ) with a corresponding compensation winding 19 or 26 (or 20 ) provided, however, two or more such ferrite rings are provided per balun half, as shown in the exemplary embodiment is shown, if necessary, corresponding compensation windings can also be applied to these additional ferrite cores, in the exemplary embodiment according to FIG. 1 also on the ferrite ring 14 or in the exemplary embodiment according to FIG. 2 both on the ferrite ring 11 and on the Ferrite ring 14 .

Claims (9)

1. reflection factor measuring bridge, in which the voltage drop across the diagonal ( 2 , 3 ) is supplied to the indicator via a coaxial cable ( 7 ), the inner conductor ( 8 ) of which is connected to one ( 2 ) and the outer conductor ( 9 ) of which Another connection ( 3 ) of the bridges is connected diagonally and which forms a balancing transformer with a line section ( 13 ) connected in parallel, both the coaxial cable ( 7 ) and the line section ( 13 ) being connected to at least one ferrite core ( 11 , 12 , 14 , 15 ) is wound, characterized in that the supply of a direct voltage ( 17 ) to a test object ( 4 ) connected to the measuring bridge via a coaxial line ( 5 , 16 ) via a compensation winding ( 19 , 26 ) to the high-frequency ground ( 10 ) lying end ( 18 ) of the line section ( 13 ) of the balun, which is applied to at least one of the ferrite cores ( 14 , 15 ). 2. Measuring bridge according to claim 1, characterized in that the DC voltage source ( 17 ) via a high-frequency choke ( 22 ) with the high-frequency ground connection ( 18 ) facing away from the end ( 21 ) of the compensation winding ( 19 , 26 ) is connected. 3. Measuring bridge according to claim 1 or 2, characterized in that the winding ( 25 ) of the line piece ( 13 ) on at least one of the ferrite cores ( 14 , 15 ) is formed by a coaxial cable piece, whose inner conductor ( 26 ) forms the compensation winding and is connected to its outer conductor ( 27 ) at the high-frequency ground end ( 18 ). 4. Measuring bridge according to claim 1 or 2, characterized in that the compensation winding is formed by a winding ( 19 ) wound on at least one of the ferrite cores ( 14 , 15 ) in addition to the winding ( 25 ) of the line piece ( 13 ). 5. Measuring bridge according to claim 4, characterized in that a similar compensation winding ( 20 ) is wound on at least one of the ferrite cores ( 11 , 12 ) of the coaxial cable ( 7 ) of the symme trier transformer. 6. Measuring bridge according to claim 5, characterized in that this further compensation winding ( 20 ) with its one end ( 21 ) is connected to the DC voltage source ( 17 ). 7. Measuring bridge according to claim 6, characterized in that the connection point ( 21 ) of the direct current source ( 17 ) facing away from the end ( 18 ) is at high frequency to ground. 8. Measuring bridge according to claim 6, characterized in that the connection point ( 21 ) of the direct current source ( 17 ) facing away from the end ( 28 ) of this additional compensation winding ( 20 ) via a resistor ( 24 ) with the high-frequency end ( 18 ) the compensation winding ( 19 ) of the line section ( 13 ) of the balun is connected. 9. Measuring bridge according to one of the preceding claims, characterized in that the DC voltage is supplied via a low-pass filter ( 23 ).